Penicillins intermediates

Streptococcus pneumoniae Penicillin susceptible Penicillin intermediate Penicillin resistant Group B Streptococcus Staphylococcus aureus Methicillin susceptible Methicillin resistant Staphylococcus epidermidis Listeria monocytogenes... 

Erythromydn, FCd- doxycydine, azithromydn, darithromydrP Penicillin intermediate (MIC O.I-I.O mcg(mL)... 

Penicillin-intermediate resistance (MIC <0.1 <2 pg/mL) Penicillin-high level resistance (MIC >2 pg/mL)... 

Semacylase. [Novo Notdisk] Pen-v-acylase enzyme fmr mfg. of penicillin intermediates. 

Participation by sulfur has also been noted in attempts to hydrolyze the imino chloride functionality of penicillin intermediates, e.g., as in (66), to amide groups. Treatment of (66) with silver nitrate or aqueous acid resulted in the formation of three products, (67)-(69). Their formation can be rationalized as shown in Eq. (20). ... 

Therapeutics. Compounds containing the furan or tetrahydrofuran ring are biologically active and are present in a number of pharmaceutical products. Eurfurjdamine [617-89-0] is an intermediate in the diuretic, furosemide. Tetrahydrofurfurylamine [4795-29-3] may also have pharmaceutical applications. 5-(E)imethyiaininomethyi)furfuryi alcohol [15433-79-17 is an intermediate in the preparation of ranitidine, which is used for treating ulcers. 2-Acet5dfuran [1192-62-7] prepared from acetic anhydride and furan is an intermediate in the synthesis of cefuroxime, a penicillin derivative. 2-Euroic acid is prepared by the oxidation of furfural. Both furoic acid [88-14-2] and furoyl chloride [527-69-5] are used as pharmaceutical intermediates. 

Other Reactions. The reaction of Thydioxybenzaldehyde with sodium cyanide and ammonium chloride, Strecker synthesis, yields /J-hydroxyphenylglycine [938-97-6] a key intermediate in the manufacture of semisynthetic penicillins and cephalosporins (see Antibiotics, p-LACTAMs). 

Pharmaceuticals. -Hydroxybenzaldehyde is often a convenient intermediate in the manufacture of pharmaceuticals (qv). For example, 2-(p-hydroxyphenyl)glycine can be prepared in a two-step synthesis starting with -hydroxybenzaldehyde (86). This amino acid is an important commercial intermediate in the preparation of the semisynthetic penicillin, amoxicillin (see ANTIBIOTICS, P-LACTAMs). Many cephalosporin-type antibiotics can be made by this route as well (87). The antiemetic trimethobenzamide [138-56-7] is convenientiy prepared from -hydroxybenzaldehyde (88) (see Gastrointestinal agents). 

In a similar way, several cephalosporins have been hydrolyzed to 7-aminodeacetoxycephalosporanic acid (72), and nocardicin C to 6-aminonocardicinic acid (73). Penicillin G amidase from Pscherichia coli has been used in an efficient resolution of a racemic cis intermediate required for a preparation of the synthon required for synthesis of the antibiotic Loracarbef (74). The racemic intermediate (21) underwent selective acylation to yield the cis derivative (22) in 44% yield the product displayed a 97% enantiomeric excess (ee). 

TicarcHHn [34787-01-4] (SB) (52) is a significant penicillin antibiotic that incorporates the thiophene ring system. A number of routes to the required intermediate, 3-thiophenemalonic acid [21080-92-2] have been used over the years. Those from thiophene-based starting materials have involved 3-methylthiophene and 3-bromothiophene. 

MisceUaneous uses include extraction and purification of penicillin, alkaloids, vitamins, and flavors, and as an intermediate in the preparation of dyes and pesticides. Chloroform has also been used as a fumigant and insecticide, in the formulation of cough symps, toothpastes, liniments, and toothache preparations. These latter uses were banned by the FDA in 1976 (38). 

The second most important group of immobilized enzymes is stiU the penicillin G and V acylases. These are used in the pharmaceutical industry to make the intermediate 6-aminopenici11anic acid [551-16-6] (6-APA), which in turn is used to manufacture semisynthetic penicillins, in particular ampicilHn [69-53-4] and amoxicillin [26787-78-0]. This is a remarkable example of how a complex chemical synthesis can be replaced with a simple enzymatic one ... 

Cephalosporin 5-oxides and penicillin 5-oxides (221) can be converted into isothiazol-3-ones (222) by the action of bases. These reactions proceed via an intermediate azetidinonesulfenic acid (223 Scheme 37) (77SST(4)339). Attempts to prepare /3-lactam compounds from isothiazoles have, as yet, been unsuccessful (81X2181). 

As many natural and synthetic /3-lactams bear 3-acylamino substituents, the corresponding free amines or protected forms thereof are versatile synthetic intermediates. They may be prepared in several ways, for example by deacylation of the 7-amido group in naturally occurring penicillins by enzymic or chemical means. Chemical degradation usually involves conversion of the amide to a chloroimidate followed by cleavage with aqueous alcohols (75S547 p. 560, 78T1731 p. 1753). 

Intermediates in penicillin and cephalosporin synthesis 78T1731, X = NR, O 75S547... 

At Smith Kline French a general approach to cephalosporin and penicillin nuclear analogs was developed that utilizes a monocyclic /3-lactam (59) with the correct cis stereochemistry as a key intermediate. This is prepared by reaction of the mixed anhydride of azidoacetic acid and trifluoroacetic acid with imine (58) followed by oxidative removal of the dimethoxybenzyl group. This product could be further elaborated to intermediate (60) which, on reaction with a -bromoketones, provides isocephalosporins (61). These nuclear analogs displayed antibacterial properties similar to cephalosporins (b-79MI51000). 

Penicillin sulfoxides can be epimerized by heat to afford thermal equilibrium mixtures of a- and /3-sulfoxides, the position of the equilibrium depending on the C(6) side chain (Scheme 5). Deuterium incorporation studies support a sulfenic acid, e.g. (18), as the intermediate in these transformations. This mechanism is also supported by the finding that when an a-sulfoxide epimerizes to a /3-sulfoxide there is a simultaneous epimerization at C(2) (71JCS(C)3540). With irradiation by UV light it is possible to convert a more thermodynamically stable /3-sulfoxide to the a-sulfoxide (69JA1530). 

The intermediate sulfenic acid derived from a penicillin sulfoxide has been trapped by a large assortment of reagents and, in one case, the sulfenic acid itself has been isolated (74JA1609). Only some of these products will be discussed here, and the reader is referred to the cited reviews (especially B-80MI51102) for additional examples. 

Application of the Curtius reaction to the 3-carboxyl of a penicillin has provided intermediates which have been used for the construction of cephem derivatives. As can be seen in Scheme 23, this route allows the selective cleavage of the C(3)—N(4) bond of the thiazolidine ring, thereby allowing a reconstruction of that ring in a different form (72HCA388 and the following three papers). The preparation of a related intermediate is shown in Scheme 24 (76HCA2298). 

Another route to a certain class of 6a-methoxypenicillanates (77TL3831) also probably involves the intermediacy of a 6-imino species. As shown in Scheme 46, 6/3-ketenimino intermediates are readily formed with penicillins having this kind of side chain. Chlorination followed by treatment with methoxide affords the 6a-methoxy-6/3-ketimine, probably involving the intermediates shown. 

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